Original reading apparatus, method for controlling the same, and storage medium

ABSTRACT

An original reading apparatus conveys an original placed on an original stacking unit, reads the conveyed original, makes a setting about whether to validate a function of interrupting conveyance of originals upon detection of double feed of the originals during conveyance of the originals in accordance with detection of originals stacked on the original stacking unit, detects an original placed on the original stacking unit, and validates the function based on the made setting in accordance with detection of the original by the original detection unit.

This application is a continuation of application Ser. No. 15/220,105filed Jul. 26, 2016, currently pending; and claims priority under 35U.S.C. § 119 to Japan Application 2015-155394 filed in Japan on Aug. 5,2015; and the contents of all of which are incorporated herein byreference as if set forth in full.

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates to an original reading apparatus whichdetects double feed of originals, a method for controlling the same, anda storage medium.

Description of the Related Art

There is available an original reading apparatus which conveys anoriginal from an ADF (Auto Document Feeder) to read an image on theoriginal, and detects the occurrence of double feed of conveyedoriginals by using a double feed detection sensor such as an ultrasonicsensor. Japanese Patent Laid-Open No. 2015-106817 has proposed anoriginal reading apparatus which makes a setting about whether to stopan original reading operation upon detection of double feed of originalsand controls whether to stop an original reading operation or continuethe operation without stopping it upon detection of double feed.

The above related art has the following problem. A user who desires todetect double feed of originals wants to automatically validate afunction of stopping an original reading operation upon detection ofdouble feed when placing originals on an ADF. However, when executing ajob to read originals, such as envelopes, for which it is not necessaryto stop a reading operation even upon detection of double feed, it isnecessary to temporarily invalidate the double feed detection functionwith respect to the reading operation of the job.

SUMMARY OF THE INVENTION

The present invention enables realization of a mechanism which detectsoriginals stacked on an original stacking unit and suitably switches adouble feed detection function between valid and invalid modes.

One aspect of the present invention provides an original readingapparatus comprising: a conveying unit configured to convey an originalplaced on an original stacking unit; a reading unit configured to readthe original conveyed by the conveying unit; a setting unit configuredto make a setting about whether to validate a function of interruptingconveyance of originals upon detection of double feed of the originalsduring conveyance of the originals by the conveying unit in accordancewith detection of originals stacked on the original stacking unit; anoriginal detection unit configured to detect an original placed on theoriginal stacking unit; and a control unit configured to validate thefunction based on the setting made by the setting unit in accordancewith detection of the original by the original detection unit.

Another aspect of the present invention provides a method forcontrolling an original reading apparatus, the method comprising:conveying an original placed on an original stacking unit; reading theoriginal conveyed in the conveying; making a setting about whether tovalidate a function of interrupting conveyance of originals upondetection of double feed of the originals during conveyance of theoriginals in the conveying in accordance with detection of originalsstacked on the original stacking unit; detecting an original placed onthe original stacking unit; and validating the function based on thesetting made in the setting in accordance with detection of the originalin the detecting.

Still another aspect of the present invention provides a non-transitorycomputer-readable storage medium storing a computer program for causinga computer to execute a method for controlling an original readingapparatus, the method comprising: conveying an original placed on anoriginal stacking unit; reading the original conveyed in the conveying;making a setting about whether to validate a function of interruptingconveyance of originals upon detection of double feed of the originalsduring conveyance of the originals in the conveying in accordance withdetection of originals stacked on the original stacking unit; detectingan original placed on the original stacking unit; and validating thefunction based on the setting made in the setting in accordance withdetection of the original in the detecting.

Further features of the present invention will be apparent from thefollowing description of exemplary embodiments with reference to theattached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram showing an image reading system;

FIG. 2 is a block diagram showing an arrangement associated with controlof a reading unit;

FIG. 3 is a sectional view of the reading unit;

FIG. 4 is a view showing the outer appearance of an operation unit;

FIGS. 5A-5C are views showing an operation screen displayed on a panel401;

FIGS. 6A and 6B are views showing an operation screen displayed on thepanel 401;

FIGS. 7A-7C are views showing an operation screen displayed on the panel401;

FIGS. 8A-8C are views showing an operation screen displayed on the panel401;

FIG. 9 is a flowchart showing a control method for controlling theexecution of copying;

FIG. 10 is a flowchart showing a control method for controlling theexecution of copying; and

FIG. 11 is a flowchart showing a control method for controlling theexecution of copying.

DESCRIPTION OF THE EMBODIMENTS

Embodiments of the present invention will now be described in detailwith reference to the drawings. It should be noted that the relativearrangement of the components, the numerical expressions and numericalvalues set forth in these embodiments do not limit the scope of thepresent invention unless it is specifically stated otherwise.

First Embodiment

The first embodiment of the present invention will be described below.This embodiment executes a job to read (to be referred to as “scan”hereinafter) reading target originals placed on an ADF. In this case,before executing the job, the user can make a setting about whether tovalidate or invalidate the double feed detection function as a settingfor the job. At this time, it is possible to make a setting aboutwhether to validate the double feed detection function in conjunctionwith the placing of originals on the ADF. The embodiment is configuredto switch operation between interrupting a scan and continuing it duringthe execution of the job in accordance with a setting for the doublefeed detection function and the detection of double feed of readingtarget originals by the double feed detection sensor.

Arrangement of Image Reading Apparatus

The arrangement of an image reading apparatus (original readingapparatus) according to this embodiment will be described with referenceto FIG. 1. This embodiment will exemplify an MFP (Multi FunctionPeripheral) 101 as an example of the image reading apparatus.

The MFP 101 has a reading function of reading an image on a sheet and aprinting function of printing an image on a sheet. In addition, the MFP101 has a file transmission function of transmitting image data to aninformation processing apparatus via a network 100 and a file savefunction of saving image data in a save area in the MFP 101.

Although this embodiment will exemplify the MFP 101 as an example of theimage reading apparatus, this is not exhaustive. The embodiment can beapplied to any image reading apparatus configured to convey originals toread images on the originals. More specifically, the image readingapparatus may be a scanner which generates image data from an originaland transmits the generated image data to an information processingapparatus such as an external server. In addition, the image readingapparatus may be a scanner which saves data in an external memory (forexample, a USB flash drive) detachable from an image reading apparatusvia an external bus such as a USB. Assume that in the embodiment, forexample, the image reading apparatus includes various types ofconstituent elements described below.

The MFP 101 includes a control unit 110, an operation unit 116, areading unit 118, and a printing unit 120. In addition, the control unit110 includes a CPU 111, a ROM 112, a RAM 113, a storage 114, anoperation unit I/F 115, a reading unit I/F 117, a printing unit I/F 119,and a communication unit I/F 123.

The control unit 110 including the CPU 111 comprehensively controls theoverall operation of the MFP 101. The CPU 111 reads out control programsstored in the ROM 112 or the storage 114 and performs various types ofcontrol such as read control and print control. The ROM 112 storescontrol programs which can be executed by the CPU 111. The RAM 113 isthe main memory of the CPU 111, and is used as a work area or a temporalstorage area into which various types of control programs stored in theROM 112 and the storage 114 are loaded. The storage 114 stores printdata, image data, various types of programs, and various types ofsetting information. In this embodiment, an auxiliary storage devicesuch as an HDD is assumed to be used as the storage 114. However, anonvolatile memory such as an SSD may be used instead of an HDD.

Note that the MFP 101 according to this embodiment executes each type ofprocessing shown in flowcharts (to be described later) by using onememory (RAM 113) of one CPU 111. However, the embodiment may haveanother form. For example, each type of processing shown in flowcharts(to be described later) can be executed by cooperative operation betweenpluralities of CPUs, RAMS, ROMs, and storages. In addition, someprocessing may be executed by using a hardware circuit such as an ASICor FPGA.

The operation unit I/F 115 connects the operation unit 116 to thecontrol unit 110. FIG. 4 shows an external view of the operation unit116. The operation unit 116 includes a panel 401 for displaying anoperation screen and a hard key input unit 402. The panel 401 is, forexample, a touch panel display. The hard key input unit 402 includesvarious types of hard keys such as a start key 412 and asetting/registration key 413. The user inputs an instruction by touchingkeys displayed on the panel 401 or pressing various types of hard keysof the hard key input unit 402. Note that the panel 401 may be a displayhaving no touch panel function. In this case, the hard key input unitmay include a scroll key for selecting keys displayed on the display anda decision key for deciding the keys instead of performing a key inputoperation by a touch operation. The operation unit 116 functions as areception unit for receiving instructions issued by the user via thepanel 401 and the hard key input unit 402 and functions as a displayunit for displaying an operation screen on the panel 401 as needed.

The reading unit I/F 117 connects the reading unit 118 to the controlunit 110. The reading unit 118 reads an image on a sheet (original) togenerate image data. The image data generated by the reading unit 118 istransmitted to a PC 102 via the network 100 or printed on a sheet. Thespecific arrangement of the reading unit 118 will be described laterwith reference to FIGS. 2 and 3.

The printing unit I/F 119 connects the printing unit 120 to the controlunit 110. The control unit 110 transfers image data to be printed to theprinting unit 120 via the printing unit I/F 119. The printing unit 120receives a control command and the image data to be printed via thecontrol unit 110, and prints an image based on the image data on asheet. The printing scheme of the printing unit 120 may be anelectrophotographic scheme or inkjet scheme. The printing scheme may beanother method (for example, a thermal transfer scheme) as long as itcan print an image on a sheet.

In addition, the control unit 110 is connected to the network 100 viathe communication unit I/F 123. The communication unit I/F 123 transmitsimage data and information to the PC 102 on the network 100 or receivesprint data and information from the PC 102 on the network 100.

The PC 102 can execute various types of programs such as applicationprograms. In addition, a scanner driver and a scan application areinstalled in the PC 102. The scanner driver enables the PC 102 to usethe reading function of the MFP 101. The scan application is used toprocess and organize scanned images. Issuing a scan instruction from thePC 102 to the MFP 101 allows the use of the reading function of the MFP101.

Arrangement of Reading Unit

The hardware arrangement of the reading unit 118 included in the MFP 101will be described next with reference to FIGS. 2 and 3. FIG. 2 shows anarrangement associated with control of the reading unit 118. A CPU 131controls the operation of the reading unit 118. The CPU 131 reads outcontrol programs stored in a ROM 132, and performs various types ofcontrol operations such as read control and communication with thecontrol unit 110. The ROM 132 stores control programs which can beexecuted by the CPU 131. A RAM 133 is the main memory of the CPU 131,and is used as a work area or a temporal storage area into which varioustypes of control programs stored in the ROM 132 are loaded. Note thatthe CPU 131, the ROM 132, and the RAM 133 may be implemented by amicrocontroller having the same functions integrated in one integratedcircuit.

The reading unit 118 further includes an image processing unit 142, aCCD (Charge Coupled Device) sensor 144, an original detection sensor145, a motor control unit 147, a motor 148, a double feed detectionsensor 149, and other conveyance sensors 146. In addition, the readingunit 118 is connected to the control unit 110 via the reading unit I/F117.

The original detection sensor 145 detects that originals 203 are stackedon an original stacking unit (original feed tray) 202 (to be describedlater) of the reading unit 118. Note that a detection signal obtained bythe original detection sensor 145 is transmitted to the CPU 111 via thereading unit I/F 117.

The motor 148 is driven to rotate an original feed roller 204, conveyrollers 206, a large roller 208, a roller 209, a roller 210, a roller211, and an original delivery roller pair 207 (which will be describedlater) of the reading unit 118. In addition, the motor 148 is driven tomove an exposure unit 213 and a mirror unit 214 (which will be describedlater) of the reading unit 118. Note that in this embodiment, the CPU111 controls the driving of the motor 148 by controlling the motorcontrol unit 147. However, this is not exhaustive. The CPU 131 of thereading unit 118 may control the driving of the motor 148 by controllingthe motor control unit 147.

The double feed detection sensor 149 detects the occurrence of doublefeed during the conveyance of originals. Note that the detection signalobtained by the double feed detection sensor 149 is transmitted to theCPU 111 via the reading unit I/F 117. The double feed detection sensor149 will be described in detail later with reference to FIG. 3. Theconveyance sensors 146 are a plurality of sensors provided at properpositions on the convey path of originals, and detect the occurrence ofjam and the presence/absence of an original. An A/D conversion unitconverts data read by the CCD sensor 144 from an analog signal into adigital signal. Thereafter, the image processing unit 142 converts thedigital signal into image data, which is temporarily stored in the RAM113 via the reading unit I/F 117. The image data is saved in the storage114 under the control of the CPU 111.

A case in which the reading unit 118 reads images on the originals 203by using the ADF will be described next with reference to FIG. 3. Whenthe original detection sensor 145 detects that the original 203 isstacked on the stacking unit 202, scanning is started in accordance withthe reception of a scan execution instruction from the user.

The originals 203 stacked on the stacking unit 202 are conveyed one byone by a pair of the original feed roller 204 and a separation pad 205.The originals 203 conveyed one by one pass through the double feeddetection sensor 149. The double feed detection sensor 149 detects theoccurrence of double feed of the conveyed originals 203. In this case,double feed is a state in which when originals are conveyed, two or moreoriginals are conveyed while at least partly overlapping. For example,the double feed detection sensor 149 using ultrasonic waves transmitsultrasonic waves from the upper sensor, and detects a change with thelower sensor, thereby detecting double feed. When the receptionintensity of an actually detected signal is lower than the receptionintensity of a signal detected at the time of the conveyance of thesingle original 203 as a reference, the double feed detection sensor 149determines the occurrence of double feed.

Note that this embodiment will exemplify a sensor using ultrasonic wavesas the double feed detection sensor 149. However, it is possible to usean optical sensor as long as it can detect double feed. Alternatively,it is possible to determine the occurrence of double feed of theoriginals 203 with reference to measurement data obtained by measuringthe thickness of the original 203.

The original 203 passing through the double feed detection sensor 149 isfed into the apparatus by the convey rollers 206. An original passagedetection sensor 150 as one of the conveyance sensors 146 detects theoriginal 203 conveyed by the convey rollers 206. The original passagedetection sensor 150 then determines, based on the detection time,whether the first original 203 has passed. The large roller 208 and theroller 209 convey the original 203 fed into the apparatus by the conveyrollers 206. The large roller 208 and the roller 210 further convey theoriginal 203. The large roller 208 and the roller 211 further convey theoriginal 203 after it is conveyed between the large roller 208 and anoriginal guide plate 217 while being in contact with an original glass212 and passes through a jump ramp 218. The original delivery rollerpair 207 delivers the original 203 onto a delivery tray 222. Assume thatthe CPU 111 rotates the respective rollers by driving the motor 148 toconvey the original 203. In addition, a delivery sensor 151 as one ofthe conveyance sensors 146 detects the delivery of an original onto thedelivery tray 222.

When the original 203 passes on the original glass 212, the exposureunit 213 exposes a surface of the original 203 which is in contact withthe original glass 212 to light, thereby reading an image on theoriginal 203 in the main scanning direction and the sub-scanningdirection. The resultant reflected light from the original 203 istransmitted to the mirror unit 214 via a plurality of mirrors. Thetransmitted reflected light passes through a lens 215 and is focused.The CCD sensor 144 then converts the light into electrical signal data.The image processing unit 142 converts the data output from the CCDsensor 144 into image data, and transfers it to the control unit 110.

Note that this embodiment has exemplified the optical system of thereading unit 118 as a reduction optical system, which forms reflectedlight from the original 203 into an image on the CCD sensor 144.However, this is not exhaustive. The optical system of the reading unit118 may be a 1:1 optical system which forms reflected light from theoriginal 203 into an image on a CIS (Contact Image Sensor). Note thatthe above description has been made on the case in which the readingunit 118 reads the image on the original 203 while the position of theoptical system is fixed, and the original 203 is conveyed by the ADF.However, this is not exhaustive. It is possible to read an image on anoriginal 220 by driving the motor 148 to move the optical system whilethe original 220 is placed on a platen glass 221 (original table), andthe position of the original 220 is fixed.

A cover 250 covers part of the convey path of the ADF. The cover 250 isconfigured to pivot about a fulcrum shaft 251 so as to be openable andclosable. The user can open the cover 250 and perform, for example, ajam process, that is, removing an original jammed in the convey path oran original stopping in the convey path. Note that this embodiment mayinclude an opening/closing sensor which detects whether the cover 250 isopen or closed.

Double Feed Detection Setting

Specific control for making a setting, as a job setting, about whetherto validate or invalidate the double feed detection function will bedescribed by taking as an example the copy function of the MFP 101 withreference to FIGS. 5A-5C.

Copy settings will be described first. FIGS. 5A-5C show an example ofthe transition of a copy screen displayed on the panel 401. A screen 501is an example of a main menu screen. A screen 503 is an example of acopy setting screen. A screen 505 is another example of the copy settingscreen.

When the power of the MFP 101 is turned on to activate the MFP 101, theCPU 111 displays the main menu screen 501 as an initial screen on thepanel 401. The user of the MFP 101 can select the copy function from themain menu screen 501 displayed on the panel 401. Assume that buttons(icons) for activating various types of functions (for example, a filesave function and a file transmission function) of the MFP 101 areselectably displayed on the main menu screen 501. The CPU 111 displaysthe copy setting screen 503 in accordance with the pressing of a copyfunction button 502 by the user while the main menu screen 501 isdisplayed.

The user can make various copy settings via the copy setting screen 503.For example, the user can make settings such as settings concerning thenumber of copies and double-sided printing. Note that copy job settingsinclude many setting items which are not exemplarily shown herein. Forthis reason, it is difficult to make all settings within one screen.Assume therefore that the user makes settings for a plurality offunctions by making transition to an individual setting screen for eachsetting item.

A double feed detection key 504 provided on the copy setting screen 503is a virtual key for selecting whether to validate or invalidate thedouble feed detection function. The user can change a setting, as a jobsetting, about whether to detect the occurrence of double feed using thedouble feed detection key 504. The copy setting screen 503 in FIG. 5Bexemplifies a case in which a setting is made not to detect theoccurrence of double feed. If “a setting not to detect the occurrence ofdouble feed” according to this embodiment has been made, the conveyanceof an original is not stopped even if the double feed detection sensor149 detects double feed. Therefore, “a setting not to detect theoccurrence of double feed” can be a setting not to stop the conveyanceof an original even if the double feed detection sensor 149 detectsdouble feed.

The CPU 111 displays the copy setting screen 505 in accordance with thepressing of the double feed detection key 504 by the user while the copysetting screen 503 is displayed. The copy setting screen 505 exemplifiesa case in which a setting is made to detect the occurrence of doublefeed on the copy setting screen 505. If “a setting to detect theoccurrence of double feed” according to this embodiment is made, theconveyance of an original is stopped in accordance with the detection ofdouble feed by the double feed detection sensor 149. Therefore, “asetting to detect the occurrence of double feed” can be a setting tostop the conveyance of an original in accordance with the detection ofdouble feed by the double feed detection sensor 149. In addition, theCPU 111 according to this embodiment performs control to display thedouble feed detection key in a color different from that of the doublefeed detection key 504 as indicated by a double feed detection key 506to notify the user that a setting is made to detect the occurrence ofdouble feed. In this case, display is performed in different colors.However, the present invention is not limited to this. For example, thedouble feed detection key 506 may be displayed in a shape different fromthat of the double feed detection key 504. Alternatively, the doublefeed detection key 504 may be displayed while not blinking, and thedouble feed detection key 506 may be displayed while blinking.

Original Detection Setting

There follows a description, with reference to FIGS. 6A and 6B, ofspecific control when registering, as a device setting, a settingwhether to switch from a setting not to detect the occurrence of doublefeed in accordance with the detection of an original to a setting todetect the occurrence of double feed. FIGS. 6A and 6B show an example ofthe transition of a setting/registration screen displayed on the panel401. A screen 601 is an example of a setting/registration menu screen. Ascreen 604 is an example of a setting change screen. A screen 607 isanother example of the setting change screen. A screen 610 is anotherexample of the setting/registration menu screen.

The CPU 111 displays the setting/registration menu screen 601 on thepanel 401 in accordance with the pressing of the setting/registrationkey 413 of the hard key input unit 402. The setting/registration menuscreen 601 displays the value “OFF” as information 602, which indicatesthat the user has not made a setting to switch the double feed detectionkey 504 shown on the copy setting screen 503 to the double feeddetection key 506 shown on the copy setting screen 505 when an originalis detected. A default setting menu 603 for feeder double feed detectionis a menu for transition to the setting change screen.

Upon detecting the pressing of the default setting menu 603 for feederdouble feed detection, the CPU 111 displays the setting change screen604 on the panel 401. The setting change screen 604 displays an OFF key605 and an ON key 606. In this case, when the OFF key 605 ishighlighted, it indicates that there will be no switching from thesetting not to detect the occurrence of double feed in accordance withthe detection of an original to the setting to detect the occurrence ofdouble feed. That is, the current default setting for feeder double feeddetection is OFF.

The CPU 111 displays the setting change screen 607 on the panel 401 inaccordance with the pressing of the ON key 606 by the user while thesetting change screen 604 is displayed. When an ON key 608 ishighlighted on the setting change screen 607, it indicates thatswitching is made from the setting not to detect the occurrence ofdouble feed in accordance with the detection of an original to thesetting to detect the occurrence of double feed.

The CPU 111 displays the setting/registration menu screen 610 on thepanel 401 in accordance with the pressing of an OK key 609 by the user(user input) while the setting change screen 607 is displayed. In thiscase, the CPU 111 sets the value of a flag (to be referred to as anoriginal detection setting flag hereinafter) to “TRUE” (valid). Thisflag indicates whether to switch from a setting not to cope with doublefeed when it occurs upon detection of an original to a setting to copewith the occurrence of double feed. Note that the value of the originaldetection setting flag is temporarily stored in the RAM 113. Note thatwhen the original detection setting flag is “TRUE”, it indicates thatthe double feed detection key 504 displayed on the copy setting screen503 is switched to the double feed detection key 506 displayed on thecopy setting screen 505 when an original is detected. With this setting,when double feed is detected, error processing or the like is performedto eliminate the double feed. This embodiment will exemplify a case inwhich error processing is performed so as to stop the conveyance of anoriginal. However, error processing may be performed so as to stop anoriginal reading operation while continuing the conveyance of anoriginal. When the original detection setting flag is “FALSE” (invalid),it indicates that when an original is detected, there is no switchingfrom the double feed detection key 504 displayed on the copy settingscreen 503 to the double feed detection key 506 displayed on the copysetting screen 505. With this setting, even if double feed is detected,no measure is taken, and the conveyance of the original is continued.The setting/registration menu screen 610 displays the value “ON” asinformation 611, which indicates that a setting is made to switch fromthe double feed detection key 504 displayed on the copy setting screen503 to the double feed detection key 506 displayed on the copy settingscreen 505 when an original is detected.

Specific control to be performed when the original detection settingflag is “TRUE” will be described next with reference to FIGS. 7A-7C byexemplifying the copy function of the MFP 101. FIGS. 7A-7C show anexample of the transition of a copy screen displayed on the panel 401.

The CPU 111 displays a copy setting screen 701 on the panel 401 inaccordance with the pressing of the copy function button 502 displayedon the main menu screen 501 by the user while no original 203 is stackedon the stacking unit 202. The CPU 111 displays a copy setting screen 703on the panel 401 in accordance with the stacking of the originals 203 onthe stacking unit 202 by the user while the copy setting screen 701 isdisplayed. The copy setting screen 703 exemplifies a case in which asetting is made to detect the occurrence of double feed as indicated bya double feed detection key 704. The double feed detection key 704 isdisplayed in a color different from that of a double feed detection key702. In this case, these keys are displayed in different colors.However, the present invention is not limited to this. For example, thedouble feed detection key 704 may be displayed in a shape different fromthat of the double feed detection key 702. Alternatively, while thedouble feed detection key 702 is displayed without blinking, the doublefeed detection key 704 may be displayed with blinking.

When the user removes the original 203 from the stacking unit 202 whilethe copy setting screen 703 is displayed, the CPU 111 displays a copysetting screen 705 on the panel 401. The copy setting screen 705exemplifies a case in which no setting is made to detect the occurrenceof double feed as indicated by a double feed detection key 706.

Processing at Time of Detection of Double Feed

Assume that the reading unit 118 of the MFP 101 reads originals. In thiscase, when double feed occurs, since a plurality of originals in astacked state flow along the convey path, original jam is likely tooccur midway along the path. Even if the originals successfully passthrough the convey path, since image data is read while the twooriginals are stacked on each other, the generated image data lacks insome original information. In this embodiment, therefore, a setting ismade, as a job setting, to validate the double feed detection function.In addition, when double feed occurs, control is performed totemporarily stop the conveyance of originals and notify the user of thedetection of the double feed.

Specific control to be performed until the user completes re-reading ofan original after resetting the original on the ADF upon reception of anotification of double feed will be described with reference to FIGS.8A-8C by exemplifying the copy function of the MFP 101. FIGS. 8A-8C showan example of the transition of a screen displayed on the panel 401 whenthe double feed detection sensor 149 of the reading unit 118 detects theoccurrence of double feed.

A screen 801 is an example of a copy setting screen. A screen 803 is anexample of a copy execution screen. A screen 804 is an example of aguide screen for displaying information which notifies the user of theoccurrence of double feed. A screen 806 is an example of a screen forwaiting for re-reading of an original. A screen 809 is another exampleof the copy execution screen. A screen 810 is another example of thecopy setting screen.

The copy setting screen 801 exemplifies a case in which a setting ismade to detect the occurrence of double feed as indicated by a doublefeed detection key 802. Upon detecting that the start key 412 is pressedwhile the copy setting screen 801 is displayed, the CPU 111 starts copyprocessing. The CPU 111 causes the reading unit 118 to start an originalreading operation, and displays the copy setting screen 803 on the panel401.

When the double feed detection sensor 149 detects the occurrence ofdouble feed while an original is read by the copy function, the CPU 111interrupts the conveyance of the original. Note that instead ofinterrupting the conveyance of an original, the CPU 111 may performcontrol to interrupt an original reading operation while continuing theconveyance of the original. In addition, the CPU 111 displays the guidescreen 804 on the panel 401. Information 805 is information fornotifying the user of the necessity to remove the sheet and theinterruption of scanning because of the occurrence of double feed.

Subsequently, upon determining, based on the conveyance sensors 146, theopening/closing sensor, and the like, that error cancellation can bedone, the CPU 111 displays the re-read standby screen 806 on the panel401. Information 807 on the re-read standby screen 806 is informationfor notifying the user that he/she can restart processing by resettingthe original and pressing the start key 412. The user can restartreading the original by pressing the start key 412. Upon detecting thatthe start key 412 is pressed, the CPU 111 displays the copy executionscreen 809 on the panel 401.

In addition, a stop key 808 on the re-read standby screen 806 is a keyto be used to stop the copy function under execution. The user candiscard the read original and stop processing under execution bypressing the stop key 808. Upon detecting that the stop key 808 ispressed, the CPU 111 displays the copy execution screen 809 on the panel401.

Upon detecting the end of the copy processing, the CPU 111 displays thecopy setting screen 810 on the panel 401. The copy setting screen 810exemplifies a case in which no setting is made to detect the occurrenceof double feed as indicated by a double feed detection key 811.

Processing Procedure

A specific control method for executing a copy job upon reception of acopy job execution instruction will be described as an example of thecopy function with reference to the flowcharts shown in FIGS. 9 to 11.The CPU 111 executes each operation (step) in the flowcharts shown FIGS.9 to 11 by loading control programs stored in the ROM 112 or the storage114 into the RAM 113 and executing them. Note that another CPU (forexample, the CPU 131 of the reading unit 118) may execute some of thecontrol programs which implement the respective operations to implementthe operations in cooperation with other control programs.

First of all, in step S1000 shown in FIG. 9, the CPU 111 executes aseries of processing associated with switching between double feeddetection settings. The processing in step S1000 will be described indetail with reference to FIG. 10.

In step S1001, the CPU 111 determines whether the original detectionsensor 145 has detected the stacking of originals. If the CPU 111determines that the original detection sensor 145 has detected thestacking of originals (YES in step S1001), the process advances to stepS1002. If the CPU 111 determines NO in step S1001, the process advancesto step S1004.

In step S1002, the CPU 111 refers to the value of the original detectionsetting flag set on the setting change screens 604 and 607 to determinewhether the value is “TRUE”. If the value is “TRUE”, the processadvances to step S1003. If the value is “FALSE”, the CPU 111 advancesthe process to step S901 while maintaining the value of the originaldetection setting flag.

In step S1003, the CPU 111 switches to the setting to detect theoccurrence of double feed and advances the process to step S901. Morespecifically, when the user stacks the originals 203 on the stackingunit 202 while the copy setting screen 701 is displayed on the panel401, the CPU 111 displays the copy setting screen 703 on the panel 401.The copy setting screen 703 exemplifies a case in which a setting ismade to detect the occurrence of double feed as indicated by the doublefeed detection key 704. In this case, the CPU 111 functions as a displaycontrol means.

In step S1004, the CPU 111 determines whether the original detectionsensor 145 has detected the removal of an original. If the CPU 111determines that the original detection sensor 145 has detected theremoval of an original (YES in step S1004), the process advances to stepS1005. In contrast, if the CPU 111 determines NO in step S1004, theprocess advances to step S901.

In step S1005, the CPU 111 refers to the value of the original detectionsetting flag set on the setting change screens 604 and 607 to determinewhether the value is “TRUE”. If the value is “TRUE”, the processadvances to step S1006. If the value is “FALSE”, the CPU 111 advancesthe process to step S901.

In step S1006, the CPU 111 switches to the setting not to detect theoccurrence of double feed, and advances the process to step S901. Morespecifically, when the user removes the originals 203 from the stackingunit 202 while the copy setting screen 703 is displayed on the panel401, the CPU 111 displays the copy setting screen 705. The copy settingscreen 705 exemplifies a case in which a setting is made to detect theoccurrence of double feed as indicated by the double feed detection key706.

Referring back to FIG. 9, the CPU 111 determines in step S901 whether acopy job execution instruction has been received. If the CPU 111determines that a copy job execution instruction has been received (YESin step S901), the process advances to step S902. If the CPU 111determines NO in step S901, the process returns to step S1000. Morespecifically, when the user presses the start key 412 while the copysetting screen 801 is displayed on the panel 401, a copy job executioninstruction is received. In addition, if a copy job executioninstruction is received, the CPU 111 displays the copy setting screen803 on the panel 401.

In step S902, the CPU 111 sets the value of a flag (to be referred to asa scan end flag hereinafter) for indicating whether a series ofprocessing associated with reading (scanning) of an image on theoriginal 203 is normally ended to “FALSE” (initialization). Note thatthe value of the scan end flag is temporarily stored in the RAM 113. Ifthe scan end flag is “TRUE”, it indicates that scanning is normallyended. If the scan end flag is “FALSE”, it indicates that scanning isnot normally ended. For example, when a scan stop instruction isreceived or the execution of the copy job is canceled, the CPU 111determines that scanning is not properly ended, and should not rewritethe value of the scan end flag from “FALSE” to “TRUE”.

Upon execution of the processing in step S902, the CPU 111 advances theprocess to the scan processing in step S1100. In step S1100, the CPU 111executes a series of processing associated with scanning. A series ofprocessing (step S1100) associated with scanning will be described indetail below with reference to FIG. 11.

In step S1101, the CPU 111 controls the reading unit 118 to convey theoriginal 203 stacked on the stacking unit 202. In step S1102, the CPU111 controls the reading unit 118 to generate data by reading theoriginal 203 conveyed in step S1101 when it passes on the original glass212.

In step S1103, the CPU 111 controls the reading unit 118 to cause theimage processing unit 142 to convert the data read in step S1102 intoimage data. The CPU 111 controls the reading unit 118 to temporarilystore the converted image data in the RAM 113. In step S1104, the CPU111 obtains an output value from the double feed detection sensor 149and determines whether double feed of the originals conveyed in stepS1101 has occurred. If the double feed detection sensor 149 has detecteddouble feed, the process advances to step S1109. Otherwise, the processadvances to step S1105.

In step S1105, the CPU 111 controls the reading unit 118 to determinewhether reading of the original is complete. More specifically, when thetrailing end of the original is detected by the conveyance sensor 146and the reading processing and the processing of conversion to imagedata are complete, the CPU 111 determines that the original readingoperation is complete. The process then advances to step S1106. Incontrast to this, when the original is being conveyed or the processingof conversion to image data being performed, the CPU 111 determines thatthe reading of the original is not complete, and the process returns tostep S1102.

In step S1106, the CPU 111 saves, in the storage 114, the image datatemporarily stored in the RAM 113 in step S1103. In step S1107, the CPU111 determines whether any original is placed on the original feed tray.More specifically, the CPU 111 controls the reading unit 118 to obtainan output value from the original detection sensor 145. The CPU 111determines, based on the obtained value, whether the original 203 isstacked on the stacking unit 202. If the CPU 111 determines that theoriginal 203 is placed on the stacking unit 202, the process returns tostep S1101 to read the next original. If the CPU 111 determines that nooriginal 203 is stacked on the stacking unit 202, the process advancesto step S1108. In step S1108, the CPU 111 rewrites the value of the scanend flag stored in the RAM 113 to “TRUE”, and advances the process tostep S903 in FIG. 9.

Processing to be performed upon occurrence of double feed (YES in stepS1104) will be described next. In step S1109, the CPU 111 determineswhether a setting is made to detect the occurrence of double feed. If asetting is made to detect the occurrence of double feed, the processadvances to step S1110. If a setting is made not to detect theoccurrence of double feed, the process advances to step S1105. In stepS1110, the CPU 111 controls the reading unit 118 to interrupt scanning.Upon interruption of scanning, the CPU 111 stops the conveyance of theoriginal 203 or reading of an image on the original 203, and the processadvances to step S1111.

In step S1111, the CPU 111 deletes image data temporarily stored in theRAM 113 in step S1103, and the process advances to step S1112. In stepS1112, the CPU 111 displays the guide screen 804 on the panel 401. Theprocess then advances to step S1113. In step S1113, the CPU 111determines whether the recovery of an error is complete. Morespecifically, the CPU 111 controls the reading unit 118 to obtain outputvalues from the plurality of conveyance sensors 146. Upon determining,based on the obtained values, that all the conveyance sensors 146 havedetected no original, the CPU 111 determines that the recovery iscomplete. The process then advances to step S1114. If the CPU 111determines that any of the conveyance sensors 146 has detected anoriginal, the process returns to step S1112.

In step S1114, the CPU 111 displays the re-read standby screen 806 onthe panel 401. The process then advances to step S1115. In step S1115,the CPU 111 determines whether a scan stop instruction has beenreceived. More specifically, when the user presses the stop key 808, theprocess advances to step S1117. If the user does not press the stop key808, the process advances to step S1116.

In step S1117, the CPU 111 sets the value of a flag (to be referred toas a scan restart flag hereinafter) for indicating whether to restartreading (scanning) an image on the original 203 to “FALSE”. The processthen advances to step S1119. Note that the scan restart flag is a flagtemporarily stored in the RAM 113.

If the CPU 111 determines in step S1116 that the start key 412 ispressed, the process advances to step S1118. If the start key 412 is notpressed, the process returns to step S1115 to wait for the pressing ofthe key. In step S1118, the CPU 111 sets the value of the scan restartflag to “TRUE”, and the process advances to step S1119. In step S1119,the CPU 111 refers to the value of the scan restart flag. If the valueis “FALSE”, the process advances to step S903 in FIG. 9. In addition, inthis case, the CPU 111 closes the re-read standby screen 806, andswitches the screen displayed on the panel 401 to the copy executionscreen 809.

If the value is “TRUE”, the process returns to step S1101 to performreading processing for the original 203 placed again by the user. Inaddition, in this case, the CPU 111 closes the re-read standby screen806, and switches the screen displayed on the panel 401 to the copyexecution screen 809. Note that in the processing in step S1119, if aninstruction to stop scanning is issued, the CPU 111 terminates thescanning processing while setting the scan end flag to “FALSE”.

Referring back to FIG. 9, in step S903, the CPU 111 refers to the valueof the scan end flag to determine whether the value is “TRUE”. If thevalue is “TRUE”, the process advances to print processing in step S904.If the value of the scan end flag is “FALSE”, the process skips stepS904 and advances to step S905.

In step S904, the CPU 111 transfers, to the printing unit 120, the imagedata saved in the storage 114 in step S1106. In addition, the CPU 111controls the printing unit 120 to print an image on the sheet. When theprinting of the image saved in the storage 114 is complete in stepS1106, the process advances to step S905. In step S905, the CPU 111deletes the image data saved in the storage 114 in step S1106, andterminates the copy processing. In addition, in this case, the CPU 111closes the copy execution screen 809, and switches the screen displayedon the panel 401 to the copy setting screen 810.

As has been described above, this embodiment is configured to switch thesetting not to detect the occurrence of double feed to the setting todetect the occurrence of double feed in accordance with the detection oforiginals stacked on the stacking unit. This makes it possible toimprove operability when making, for each job, a setting about whetherto detect the occurrence of double feed. In addition, according to theembodiment, it is possible to make a setting about whether to switch asetting not to detect the occurrence of double feed to a setting todetect the occurrence of double feed when detecting originals stacked onthe stacking unit. This makes it possible to meet the user's demand forthe continuation of the conveyance of originals upon detection of doublefeed of the originals.

Modification

The present invention is not limited to the first embodiment describedabove and can be variously modified.

For example, the first embodiment has exemplified the case in which theconveyance of originals is interrupted in accordance with the detectionof double feed of the originals. However, the present invention is notlimited to this. For example, the CPU 111 may perform control tointerrupt only an original reading operation while keeping conveyingoriginals even when double feed of the originals is detected.

For example, although the first embodiment has exemplified the readcontrol in the copy function, the present invention can also be appliedto functions other than the function of reading originals. Morespecifically, the present invention can also be applied to a filetransmission function of transmitting the data of an original scanned bythe MFP 101 to an information processing apparatus. In addition, thepresent invention can be applied to a file save function of saving thedata of an original scanned by the MFP 101 in a save area in the MFP 101and a file save function of storing the data in an external memorydetachable from the MFP 101 via an external bus such as a USB.

Furthermore, the present invention can be applied to a case in which thePC 102 issues a scan instruction to a scanner having a single functionto make the scanner read the original, and stores the scanned image in asave area in the PC 102. In this case, a control program (for example, ascanner driver) of the PC 102 operates in cooperation with a readcontrol program of the scanner with the single function to perform theabove control. Assume that the scanner with the single function has anarrangement, of the arrangements described with reference to FIGS. 1 to3, which is necessary to read an original and exchange data with the PC102. Note however that the shape and outer appearance of the convey pathfor conveying and reading originals can be changed as needed. Asdescribed above, the present invention can also be applied to an imagereading apparatus which can detect double feed of originals and a systemincluding the image reading apparatus.

Other Embodiments

Embodiment(s) of the present invention can also be realized by acomputer of a system or apparatus that reads out and executes computerexecutable instructions (e.g., one or more programs) recorded on astorage medium (which may also be referred to more fully as a‘non-transitory computer-readable storage medium’) to perform thefunctions of one or more of the above-described embodiment(s) and/orthat includes one or more circuits (e.g., application specificintegrated circuit (ASIC)) for performing the functions of one or moreof the above-described embodiment(s), and by a method performed by thecomputer of the system or apparatus by, for example, reading out andexecuting the computer executable instructions from the storage mediumto perform the functions of one or more of the above-describedembodiment(s) and/or controlling the one or more circuits to perform thefunctions of one or more of the above-described embodiment(s). Thecomputer may comprise one or more processors (e.g., central processingunit (CPU), micro processing unit (MPU)) and may include a network ofseparate computers or separate processors to read out and execute thecomputer executable instructions. The computer executable instructionsmay be provided to the computer, for example, from a network or thestorage medium. The storage medium may include, for example, one or moreof a hard disk, a random-access memory (RAM), a read only memory (ROM),a storage of distributed computing systems, an optical disk (such as acompact disc (CD), digital versatile disc (DVD), or Blu-ray Disc (BD)™),a flash memory device, a memory card, and the like.

While the present invention has been described with reference toexemplary embodiments, it is to be understood that the invention is notlimited to the disclosed exemplary embodiments. The scope of thefollowing claims is to be accorded the broadest interpretation so as toencompass all such modifications and equivalent structures andfunctions.

This application claims the benefit of Japanese Patent Application No.2015-155394 filed on Aug. 5, 2015, which is hereby incorporated byreference herein in its entirety.

What is claimed is:
 1. An image reading apparatus comprising: anoriginal stacking tray; a first sensor that detects an original placedon the original stacking tray; a feeder that feeds the original; areader that reads the original fed by the feeder; a second sensor thatdetects multi feed of originals; an interface that receives a settingabout whether to enable or to disable a function of multi feed detectionwhich the second sensor detects the multi feed of originals; and adisplay that displays an object indicating the setting of the functionof multi feed detection in accordance with the first sensor detectingthe original placed on the original stacking tray.
 2. The apparatusaccording to claim 1, wherein in a case where the setting is made toenable to the function, the display displays the object indicating thatthe function of multi feed detection is enabled in accordance with thefirst sensor detecting originals placed on the original stacking tray.3. The apparatus according to claim 2, wherein the display emphaticallydisplays the object indicating that the function of multi feed detectionis enabled.
 4. The apparatus according to claim 2, further comprising: aconveyer that conveys originals placed on the original stacking tray,wherein in a case where the display displays the object indicating thatthe function of multi feed detection is enabled, the conveyer interruptsconveyance of originals in accordance with the second sensor detectingthe multi feed of originals conveyed by the conveyer.
 5. The apparatusaccording to claim 4, wherein the display displays a screen foreliminating jam caused by multi feed of originals in accordance with thesecond sensor detecting the multi feed of originals.
 6. The apparatusaccording to claim 5, wherein the display displays a screen forreceiving an instruction to disable the function of multi feed detectionin resumed conveyance of originals in a case where eliminated conveyanceof originals is resumed in accordance with an elimination of the jamcaused by the multi feed of originals.
 7. The apparatus according toclaim 5, wherein the display displays a screen for receiving aninstruction to resume the interrupted conveyance of originals inaccordance with an elimination of the jam caused by the multi feed oforiginals.
 8. The apparatus according to claim 1, wherein the displaydisplays an object indicating the function of multi feed detectionbefore originals is placed on the original stacking tray.
 9. Theapparatus according to claim 8, wherein in a case where the setting ismade to enable to the function, the display changes a displaying fromthe object indicating the function of multi feed detection to an objectindicating that the function of multi feed detection is enabled, inaccordance with the first sensor detecting originals placed on theoriginal stacking tray.
 10. The apparatus according to claim 8, whereinin a case where the setting is made to disable to the function, thedisplay does not change a displaying of the object indicating thefunction of multi feed detection, in accordance with the first sensordetecting originals placed on the original stacking tray.
 11. Theapparatus according to claim 10, wherein the feeder continues feeding oforiginals even if the second sensor has detected the multi feed oforiginals conveyed by the conveyer in a case where the displaying of theobject indicating the function of multi feed detection is not changedeven if the first sensor has detected that originals is placed on theoriginal stacking tray.
 12. The apparatus according to claim 1, whereinthe interface receives, from a user, an instruction for changing adisplaying of an object indicating the setting of the function of multifeed detection, wherein the displaying of the object indicating thefunction of multi feed detection can be changed in accordance with areception of the instruction.
 13. The apparatus according to claim 1,wherein the display displays a reception screen for receiving, from auser, the setting about whether to enable or to disable the function,and the reception screen is different from a screen including an objectindicating the setting of the function of multi feed detection.
 14. Amethod for controlling an image reading apparatus which comprises anoriginal stacking tray, a first sensor that detects an original placedon the original stacking tray, a feeder that feeds the original, areader that reads the original fed by the feeder, and a second sensorthat detects multi feed of originals, wherein the method comprises:receiving a setting about whether to enable or to disable a function ofmulti feed detection which the second sensor detects the multi feed oforiginals; and displaying an object indicating the setting of thefunction of multi feed detection in accordance with the first sensordetecting the original placed on the original stacking tray.
 15. Anon-transitory computer-readable storage medium storing a computerprogram for causing a computer to execute a method for controlling animage reading apparatus which comprises an original stacking tray, afirst sensor that detects an original placed on the original stackingtray, a feeder that feeds the original, a reader that reads the originalfed by the feeder, and a second sensor that detects multi feed oforiginals, wherein the method comprises: receiving a setting aboutwhether to enable or to disable a function of multi feed detection whichthe second sensor detects the multi feed of originals; and displaying anobject indicating the setting of the function of multi feed detection inaccordance with the first sensor detecting the original placed on theoriginal stacking tray.